Identification of polymer surface adsorbed proteins implicated in pluripotent human embryonic stem cell expansion.

Improved biomaterials are required for application in regenerative medicine, biosensing, and as medical devices. The response of cells to the chemistry of polymers cultured in media is generally regarded as being dominated by proteins adsorbed to the surface. Here we use mass spectrometry to identify proteins adsorbed from a complex mouse embryonic fibroblast (MEF) conditioned medium found to support pluripotent human embryonic stem cell (hESC) expansion on a plasma etched tissue culture polystyrene surface. A total of 71 proteins were identified, of which 14 uniquely correlated with the surface on which pluripotent stem cell expansion was achieved. We have developed a microarray combinatorial protein spotting approach to test the potential of these 14 proteins to support expansion of a hESC cell line (HUES-7) and a human induced pluripotent stem cell line (ReBl-PAT) on a novel polymer (N-(4-Hydroxyphenyl) methacrylamide). These proteins were spotted to form a primary array yielding several protein mixture 'hits' that enhanced cell attachment to the polymer. A second array was generated to test the function of a refined set of protein mixtures. We found that a combination of heat shock protein 90 and heat shock protein-1 encourage elevated adherence of pluripotent stem cells at a level comparable to fibronectin pre-treatment.

Cardiomyocytes from human pluripotent stem cells: From laboratory curiosity to industrial biomedical platform.

Cardiomyocytes from human pluripotent stem cells (hPSCs-CMs) could revolutionise biomedicine. Global burden of heart failure will soon reach USD $90bn, while unexpected cardiotoxicity underlies 28% of drug withdrawals. Advances in hPSC isolation, Cas9/CRISPR genome engineering and hPSC-CM differentiation have improved patient care, progressed drugs to clinic and opened a new era in safety pharmacology. Nevertheless, predictive cardiotoxicity using hPSC-CMs contrasts from failure to almost total success. Since this likely relates to cell immaturity, efforts are underway to use biochemical and biophysical cues to improve many of the ~30 structural and functional properties of hPSC-CMs towards those seen in adult CMs. Other developments needed for widespread hPSC-CM utility include subtype specification, cost reduction of large scale differentiation and elimination of the phenotyping bottleneck. This review will consider these factors in the evolution of hPSC-CM technologies, as well as their integration into high content industrial platforms that assess structure, mitochondrial function, electrophysiology, calcium transients and contractility. This article is part of a Special Issue entitled: Cardiomyocyte Biology: Integration of Developmental and Environmental Cues in the Heart edited by Marcus Schaub and Hughes Abriel.

Discovery of a Novel Polymer for Human Pluripotent Stem Cell Expansion and Multilineage Differentiation.

A scalable and cost-effective synthetic polymer substrate that supports robust expansion and subsequent multilineage differentiation of human pluripotent stem cells (hPSCs) with defined commercial media is presented. This substrate can be applied to common cultureware and used off-the-shelf after long-term storage. Expansion and differentiation of hPSCs are performed entirely on the polymeric surface, enabling the clinical potential of hPSC-derived cells to be realized.

Materials for stem cell factories of the future.

Polymeric substrates are being identified that could permit translation of human pluripotent stem cells from laboratory-based research to industrial-scale biomedicine. Well-defined materials are required to allow cell banking and to provide the raw material for reproducible differentiation into lineages for large-scale drug-screening programs and clinical use. Yet more than 1 billion cells for each patient are needed to replace losses during heart attack, multiple sclerosis and diabetes. Producing this number of cells is challenging, and a rethink of the current predominant cell-derived substrates is needed to provide technology that can be scaled to meet the needs of millions of patients a year. In this Review, we consider the role of materials discovery, an emerging area of materials chemistry that is in large part driven by the challenges posed by biologists to materials scientists.

Faster generation of hiPSCs by coupling high-titer lentivirus and column-based positive selection.

The protocols described here address methods used in two crucial stages in the retroviral reprogramming of somatic cells to produce human induced pluripotent stem cell (hiPSC) lines. The first is an optimized method for producing lentivirus at an efficiency 600-fold greater than previously published, and it includes conjugation of the lentivirus to streptavidin superparamagnetic particles; this process takes 8 d. The second method enables the isolation of true hiPSCs immediately after somatic cell reprogramming and involves column-based positive selection of cells expressing the pluripotency marker TRA-1-81. This process takes 2 h and, as it is directly compatible with feeder-free culture, the time burden of manually identifying and mechanically propagating hiPSC colonies is reduced drastically. Taken together, these methods accelerate the production of hiPSCs and enable lines to be isolated, expanded to approxiamtely 107 cells and cryopreserved within 6-8 weeks.

Derivation and characterisation of the human embryonic stem cell lines, NOTT1 and NOTT2.

The ability to maintain human embryonic stem cells (hESCs) during long-term culture and yet induce differentiation to multiple lineages potentially provides a novel approach to address various biomedical problems. Here, we describe derivation of hESC lines, NOTT1 and NOTT2, from human blastocysts graded as 3BC and 3CB, respectively. Both lines were successfully maintained as colonies by mechanical passaging on mouse embryonic feeder cells or as monolayers by trypsin-passaging in feeder-free conditions on Matrigel. Undifferentiated cells retained expression of pluripotency markers (OCT4, NANOG, SSEA-4, TRA-1-60 and TRA-1-81), a stable karyotype during long-term culture and could be transfected efficiently with plasmid DNA and short interfering RNA. Differentiation via formation of embryoid bodies resulted in expression of genes associated with early germ layers and terminal lineage specification. The electrophysiology of spontaneously beating NOTT1-derived cardiomyocytes was recorded and these cells were shown to be pharmacologically responsive. Histological examination of teratomas formed by in vivo differentiation of both lines in severe immunocompromised mice showed complex structures including cartilage or smooth muscle (mesoderm), luminal epithelium (endoderm) and neuroectoderm (ectoderm). These observations show that NOTT1 and NOTT2 display the accepted characteristics of hESC pluripotency.

Automated, scalable culture of human embryonic stem cells in feeder-free conditions.

Large-scale manufacture of human embryonic stem cells (hESCs) is prerequisite to their widespread use in biomedical applications. However, current hESC culture strategies are labor-intensive and employ highly variable processes, presenting challenges for scaled production and commercial development. Here we demonstrate that passaging of the hESC lines, HUES7, and NOTT1, with trypsin in feeder-free conditions, is compatible with complete automation on the CompacT SelecT, a commercially available and industrially relevant robotic platform. Pluripotency was successfully retained, as evidenced by consistent proliferation during serial passage, expression of stem cell markers (OCT4, NANOG, TRA1-81, and SSEA-4), stable karyotype, and multi-germlayer differentiation in vitro, including to pharmacologically responsive cardiomyocytes. Automation of hESC culture will expedite cell-use in clinical, scientific, and industrial applications.

Feeder-free culture of human embryonic stem cells in conditioned medium for efficient genetic modification.

Realizing the potential of human embryonic stem cells (hESCs) in research and commercial applications requires generic protocols for culture, expansion and genetic modification that function between multiple lines. Here we describe a feeder-free hESC culture protocol that was tested in 13 independent hESC lines derived in five different laboratories. The procedure is based on Matrigel adaptation in mouse embryonic fibroblast conditioned medium (CM) followed by monolayer culture of hESC. When combined, these techniques provide a robust hESC culture platform, suitable for high-efficiency genetic modification via plasmid transfection (using lipofection or electroporation), siRNA knockdown and viral transduction. In contrast to other available protocols, it does not require optimization for individual lines. hESC transiently expressing ectopic genes are obtained within 9 d and stable transgenic lines within 3 weeks.

Monoallelic expression of nine imprinted genes in the sheep embryo occurs after the blastocyst stage.

The preimplantation embryos of a range of mammals can be susceptible to disruptions in genomic imprinting mechanisms, resulting in loss of imprinting. Such disruptions can have developmental consequences involving foetal and placental growth such as Beckwith-Wiedemann syndrome in humans and large offspring syndrome in sheep. Our objective was to investigate the dynamics of establishing monoallelic expression of individual sheep imprinted genes post-fertilisation. Semi-quantitative RT-PCR was used to amplify cDNA from the sheep blastocyst, day 21 foetus and day 21 chorioallantois, to compare expression levels between biparental and parthenogenetic embryos in order to indicate allelic expression status. In common with other mammals, IGF2, PEG1 and PEG3 were paternally expressed in the day 21 conceptus, while H19, IGF2R, GRB10 and p57KIP were maternally expressed. Interestingly, GNAS was maternally expressed in the foetus, but paternally expressed in the chorioallantois at day 21. Overall, the imprinting of ovine GRB10 and IGF2R was comparable with mouse but not with human. Contrary to the trophoblast-restricted maternal expression in both mouse and human, SASH2 (sheep homologue of Mash2/HASH2) was expressed in the ovine foetus and was biallelically expressed in the chorioallantois. Differential methylation of the H19 CTCF III upstream region and IGF2R DMR2 in the chorioallantois revealed predominantly paternal and maternal methylation respectively, indicating conservation of these imprinting regulatory regions. In blastocysts, IGF2R, GRB10 and SASH2 were expressed biallelically, while the other genes were not detected. Thus, for the majority of ovine imprinted genes examined, monoallelic expression does not occur until after the blastocyst stage.

DNA methylation, insulin resistance, and blood pressure in offspring determined by maternal periconceptional B vitamin and methionine status.

A complex combination of adult health-related disorders can originate from developmental events that occur in utero. The periconceptional period may also be programmable. We report on the effects of restricting the supply of specific B vitamins (i.e., B(12) and folate) and methionine, within normal physiological ranges, from the periconceptional diet of mature female sheep. We hypothesized this would lead to epigenetic modifications to DNA methylation in the preovulatory oocyte and/or preimplantation embryo, with long-term health implications for offspring. DNA methylation is a key epigenetic contributor to maintenance of gene silencing that relies on a dietary supply of methyl groups. We observed no effects on pregnancy establishment or birth weight, but this modest early dietary intervention led to adult offspring that were both heavier and fatter, elicited altered immune responses to antigenic challenge, were insulin-resistant, and had elevated blood pressure-effects that were most obvious in males. The altered methylation status of 4% of 1,400 CpG islands examined by restriction landmark genome scanning in the fetal liver revealed compelling evidence of a widespread epigenetic mechanism associated with this nutritionally programmed effect. Intriguingly, more than half of the affected loci were specific to males. The data provide the first evidence that clinically relevant reductions in specific dietary inputs to the methionine/folate cycles during the periconceptional period can lead to widespread epigenetic alterations to DNA methylation in offspring, and modify adult health-related phenotypes.

Restriction landmark genome scanning identifies culture-induced DNA methylation instability in the human embryonic stem cell epigenome.

Widespread provision of human embryonic stem cells (hESCs) for therapeutic use, drug screening and disease modelling will require cell lines sustainable over long periods in culture. Since the short-term, in vitro culture of mammalian embryos can result in DNA methylation changes, the epigenetic stability of hESCs warrants investigation. Existing hESC lines have been derived and cultured under diverse conditions, providing the potential for programming differential changes into the epigenome that may result in inter-line variability over and above that inherited from the embryo. By examining the DNA methylation profiles of > 2000 genomic loci by Restriction Landmark Genome Scanning, we identified substantial inter-line epigenetic distance between six independently derived hESC lines. Lines were found to inherit further epigenetic changes over time in culture, with most changes arising in the earliest stages post-derivation. The loci affected varied between lines. The majority of culture-induced changes (82.3-87.5%) were stably inherited both within the undifferentiated cells and post-differentiation. Adapting a line to a serum-free culture system resulted in additional epigenetic instability. Overall 80.5% of the unstable loci uncovered in hESCs have been associated previously with an adult tumour phenotype. Our study shows that current methods of hESC propagation can rapidly programme stable and unpredictable epigenetic changes in the stem cell genome. This highlights the need for (i) novel screening strategies to determine the experimental utility and biosafety of hESCs and (ii) optimization and standardization of procedures for the derivation and culture of hESC lines that minimize culture-induced instability.

Improved human embryonic stem cell embryoid body homogeneity and cardiomyocyte differentiation from a novel V-96 plate aggregation system highlights interline variability.

Although all human ESC (hESC) lines have similar morphology, express key pluripotency markers, and can differentiate toward primitive germ layers in vitro, the lineage-specific developmental potential may vary between individual lines. In the current study, four hESC lines were cultured in the same feeder-free conditions to provide a standardized platform for interline analysis. A high-throughput, forced-aggregation system involving centrifugation of defined numbers of hESCs in V-96 plates (V-96FA) was developed to examine formation, growth, and subsequent cardiomyocyte differentiation from >22,000 EBs. Homogeneity of EBs formed by V-96FA in mouse embryo fibroblast-conditioned medium was significantly improved compared with formation in mass culture (p < .02; Levene's test). V-96FA EB formation was successful in all four lines, although significant differences in EB growth were observed during the first 6 days of differentiation (p = .044 to .001; one-way analysis of variance [ANOVA]). Cardiomyocyte differentiation potential also varied; 9.5% +/- 0.9%, 6.6% +/- 2.4%, 5.2% +/- 3.1%, and 1.6% +/- 1.0% beating EBs were identified for HUES-7, NOTT2, NOTT1, and BG01, respectively (p = .008; one-way ANOVA). Formation of HUES-7 V-96FA EBs in defined medium containing activin A and basic fibroblast growth factor resulted in 23.6% +/- 3.6% beating EBs, representing a 13.1-fold increase relative to mass culture (1.8% +/- 0.7%), consistent with an observed 14.8-fold increase in MYH6 (alphaMHC) expression by real-time polymerase chain reaction. In contrast, no beating areas were derived from NOTT1-EBs and BG01-EBs formed in defined medium. Thus, the V-96FA system highlighted interline variability in EB growth and cardiomyocyte differentiation but, under the test conditions described, identified HUES-7 as a line that can respond to cardiomyogenic stimulation.

Methylation-sensitive polymerase chain reaction.

Here, we describe a robust and reproducible methylation-sensitive polymerase chain reaction (MS-PCR) method to detect the percentage methylation in repeat sequences of individual pre-implantation ovine embryos produced by different embryo technologies. This method allows the comparison of embryos produced by nuclear transfer with other production and embryo culture methods, accounting for the heterogeneity between embryos within a single treatment. DNA extracted from single embryos is digested with a methylation-sensitive restriction enzyme to determine the percentage methylation after PCR amplification in comparison with an undigested control. The undigested control represents 100% methylation because methylation-sensitive enzymes do not cut methylated DNA, allowing the entire sample to be amplified by PCR. Image analysis quantification of the digested subsample PCR product on an ethidium bromide-stained agarose gel is proportional to the amount of methylated DNA in each embryo. By comparing quadruplicate values obtained for each embryo against a standard curve, we are able to ensure the validity of our results for each individual embryo. Compared with bisulphite sequencing methods, the method described is rapid, inexpensive, and relatively high-throughput.

Common culture conditions for maintenance and cardiomyocyte differentiation of the human embryonic stem cell lines, BG01 and HUES-7.

Development of generic differentiation protocols that function in a range of independently-derived human embryonic stem cell (hESC) lines remains challenging due to considerable diversity in culture methods practiced between lines. Maintenance of BG01 and HUES-7 has routinely been on mouse embryonic fibroblast (MEF) feeder layers using manual- and trypsin-passaging, respectively. We adapted both lines to trypsin-passaging on feeders or on Matrigel in feeder-free conditions and assessed proliferation and cardiac differentiation. On feeders, undifferentiated proliferation of BG01 and HUES-7 was supported by all three media tested (BG-SK, HUES-C and HUES-nL), although incidence of karyotypic instability increased in both lines in BG-SK. On Matrigel, KSR-containing conditioned medium (CM) promoted undifferentiated cell proliferation, while differentiation occurred in CM containing Plasmanate or ES-screened Fetal Bovine Serum (FBS) and in unconditioned medium containing 100 ng/ml bFGF. Matrigel cultures were advantageous for transfection but detrimental to embryoid body (EB) formation. However, transfer of hESCs from Matrigel back to feeders and culturing to confluence was found to rescue EB formation. EBs formed efficiently when hESCs on feeders were treated with collagenase, harvested by scraping and then cultured in suspension in CM. Subsequent culture in FBS-containing medium produced spontaneously contracting EBs, for which the mean beat rate was 37.2 +/- 2.3 and 41.1 +/- 3.1 beats/min for BG01-EBs and HUES-7-EBs, respectively. Derived cardiomyocytes expressed cardiac genes and responded to pharmacological stimulation. Therefore the same culture and differentiation conditions functioned in two independently-derived hESC lines. Similar studies in other lines may facilitate development of universal protocols.

Human embryonic stem cells as a model for nutritional programming: an evaluation.

Our laboratory is evaluating whether an epigenetic mechanism involving alterations in DNA methylation can alter the trajectory of embryonic/fetal development in response to maternal nutrients. A similar mechanism may operate in embryo culture environments commonly used in human assisted conception. Since developmental studies on early human embryos in utero are obviously not possible, we have begun to investigate the utility of human embryonic stem cells (hESC) to uncover potential programming mechanisms. This review highlights some of the advantages and problems associated with such a model and suggests that these issues are also broadly applicable to utility of hESC for more general toxicology and drug screening applications.

The effect of interspecific oocytes on demethylation of sperm DNA.

In contrast to mice, in sheep no genome-wide demethylation of the paternal genome occurs within the first postfertilization cell cycle. This difference could be due either to an absence of a sheep demethylase activity that is present in mouse ooplasm or to an increased protection of methylated cytosine residues in sheep sperm. Here, we use interspecies intracytoplasmic sperm injection to demonstrate that sheep sperm DNA can be demethylated in mouse oocytes. Surprisingly, mouse sperm can also be demethylated to a limited extent in sheep oocytes. Our results suggest that the murine demethylation process is facilitated either by a sperm-derived factor or by male pronuclear chromatin composition.

Conservation of IGF2-H19 and IGF2R imprinting in sheep: effects of somatic cell nuclear transfer.

In different mammalian species, in vitro culture and manipulation can lead to aberrant fetal and peri-natal development. It has been postulated that these diverse abnormalities are caused by epigenetic alterations and that these could affect genes that are regulated by genomic imprinting. To explore this hypothesis relative to somatic cell nuclear transfer in sheep, we investigated whether the ovine H19-IGF2 and IGF2R loci are imprinted and analysed their DNA methylation status in cloned lambs. A comparison between parthenogenetic and control concepti established that imprinting at these two growth-related loci is evolutionarily conserved in sheep. As in humans and mice, IGF2R and H19 comprise differentially methylated regions (DMRs) that are methylated on one of the two parental alleles predominantly. In tongue tissue from 12 out of 13 cloned lambs analysed, the DMR in the second intron of IGF2R had strongly reduced levels of DNA methylation. The DMR located upstream of the ovine H19 gene was found to be similarly organised as in humans and mice, with multiple CTCF binding sites. At this DMR, however, aberrant methylation was observed in only one of the cloned lambs. Although the underlying mechanisms remain to be determined, our data indicate that somatic cell nuclear transfer procedures can lead to epigenetic deregulation at imprinted loci.

Scientific hazards of human reproductive 'cloning'.

The scientific and clinical professional societies and associations covering the remit of Human Fertility are unanimously opposed to human reproductive 'cloning'. This article describes the main scientific objections to human reproductive 'cloning'. Data collected from numerous studies in a range of animal species indicate a high incidence of fetal defects, a stillbirth rate typically of more than 90% and a lack of adequate information on postnatal development. These concerns are exacerbated by misconceptions about the current ability to screen preimplantation embryos for 'cloning-induced' defects. Scientists and clinicians are sometimes treated with mistrust in the eyes of the public and media over such issues, perhaps because scientific information is not as well communicated as it might be. The duty of reproductive specialists is to convey the limits of their knowledge on this issue to the public and policymakers.

Epigenetic reprogramming: how now, cloned cow?

DNA methylation patterns are dynamic in cleavage-stage embryos of a number of mammalian species. A failure to properly recapitulate preimplantation DNA methylation patterns in embryos derived by nuclear transfer may contribute to the low efficiency of nuclear transfer in producing live offspring.